Objectives: Actual dosages of radiation received by the cochlea are challenging to quantify in
humans and animal models since the cochlea is a small organ embedded deep within the
temporal bone. It is particularly important to measure the actual dosages of radiation
being delivered to the cochlea when studying hearing preservation after stereotactic
radiosurgery for vestibular schwannoma. The objective of this study is to compare
cochlear irradiation dosages as measured by small-sized metal-oxide semiconductor-field-effect
transistor (MOSFET) probes placed directly on the cochlear promontory through a myringotomy
incision to larger standard ion chamber dosimeter (gold standard) probes positioned
at the level of the cochlea or on the mastoid surface in an adult rat phantom.
Methods: Two MOSFET probes were calibrated in a small animal irradiator against a standard
ion chamber dosimeter probe to obtain the calibration coefficient. A Norway Brown
adult rat was euthanized and placed in a custom restrainer with rigid head fixation;
the vertex was located ~8 cm from the X-ray irradiation source. One ear was exposed
to radiation, while the contralateral ear and remainder of the body were shielded
by 6 mm of lead. MOSFET probes were then placed on bilateral cochlear promontories
(via myringotomies) and the standard dosimeter probe was placed alongside the mastoid
at the level of the cochlea. Various dosages of radiation (160 kV, 25 mA; 0 to ~20
Gy) were delivered to the cochlea at ~5.35 Gy/minute, and dosages of cochlear radiation
were measured by the MOSFET and standard dosimeter probes.
Results: Radiation sensitivities of MOSFET probes were consistent; the calibration coefficient
of MOSFETs to standard ion chamber dosimetry probes ranged from 384 to 406 mV/Gy.
There were linear dose-dependent relationships between the total time of delivered
radiation and total Gy measured by the standard ion chamber dosimetry (Gy = 6.39 x
Min – 0.12; R2=1) and MOSFET probes placed in the radiated and non-radiated ears (Gy = 5.80 x Min
+ 0.01, R2=0.9999; Gy = 0.08 x Min + 0.35, R2=0.06, respectively). MOSFET probes placed on the cochlear promontory in the radiated
ear shielded with lead measured from 0.35 to 0.60 Gy of radiation. Standard ion chamber
dosimetry probes over-estimate cochlear radiation dosages in rats by 10%, when compared
to MOSFET probes placed on the cochlear promontory in radiated ears.
Conclusions: MOSFETs are small dosimeter probes that can be placed on the cochlear promontory
through myringotomies in rats. In designing radiation protocols in vivo, MOSFETs can
more accurately measure the amount of radiation received by the cochlea compared to
large standard ion chamber dosimeter probes that are positioned at the approximate
height of the cochlea or mastoid surface. Delivering accurate dosages of radiation
to the cochlea will help researchers better understand how various radiation regimens
can affect the molecular mechanisms and hearing outcomes in radiation-induced hearing
loss in vivo. Placement of MOSFET probes along the tympanic membrane in humans when
performing stereotactic radiosurgery for vestibular schwannoma may give insight into
actual radiation dosages received by the cochlea.